Method and apparatus for detecting presence of a target object via continuous laser and range of the target object via laser pulse

ABSTRACT

A multifunction detector for detecting energy reflected from the surface, the detector comprising: a focal plane array in communication with the optical receiving path; and an optical receiving path; a read-only integrated circuit in communication with the optical receiving path, integrated with a focal plane array; and a processor programmed to operate the focal plane array and read-out integrated circuit in a first mode to process signals in a first frequency band, and in a second mode to process signals in a second, wider frequency band.

The present application is a divisional of U.S. patent application Ser.No. 11/812,445, filed on Jun. 19, 2007, currently pending, the entirecontents of the application is incorporated herein by reference.

BACKGROUND

A multifunction detector is disclosed which can be part of a system forlocating an object within a field of regard, and for determining therange to the object, wherein the detector can include multiple modefunctionality, such as a focal plane array (FPA) function and a read-outintegrated circuit (ROIC) function.

Active imaging systems transmit energy into the environment anddetermine the presence of an object based on its reflection of thetransmitted energy. Objects in the environment, such as optical andelectro-optical targets, retro-reflect the transmitted energy.Retro-reflecting objects have a small reflectance angle, so thatincident energy will be reflected in approximately the same directionfrom which it is received.

An exemplary system which uses retro-reflected energy from objects inthe environment to detect or image the object is described in U.S. Pat.No. 5,408,541 (Sewell). This patent discloses using a laser to imageretro-reflecting targets once the target has been detected with radar ora thermal imaging sensor.

U.S. Pat. No. 5,449,899 (Wilson) discloses a target detector whichreceives retro-reflected laser energy from an optical target. The Wilsonpatent discloses that when a target is detected, a separate range-finderwith separate optics and detector can be pointed in a directionidentified by the target detector to determine a range to the target.

SUMMARY

A multifunction detector is disclosed for detecting energy reflectedfrom an object, the detector comprising an optical receiving path; afocal plane array in communication with the optical receiving path; aread-out integrated circuit in communication with the optical receivingpath, and integrated with the focal plane array; and a processorprogrammed to respond to outputs of the focal plane array and read-outintegrated circuit in a first mode to process signals in a firstfrequency band, and in a second mode to process signals in a second,frequency band.

A method is disclosed for detecting a location (e.g., an azimuth andelevation), and range of an object within a field of regard. Anexemplary method includes transmitting energy as an optical beam, suchas a gated continuous wave, across the field of regard (e.g.,illumination with a vertical scanning beam that is horizontally movedacross the field of regard, or a raster-like scan); receiving energyreflected from an object within the field of regard via a first opticalreceiving path to determine a location of the object using a firstdetector operated in a first mode on a first frequency band;transmitting a pulsed optical beam of energy within the field of regardin response to determining the location of the object; and receivingenergy of the pulsed optical beam reflected from the object via thefirst optical receiving path to determine a range of the object usingthe first detector operated in a second mode on a second, (e.g., widerand/or higher) frequency band.

An apparatus for detecting a location and range of an object within afield of regard, includes a first transmitter for transmitting energy asan optical beam, such as a gated continuous wave, across the field ofregard; an optical receiving path for receiving energy of the opticalbeam reflected from the object; and a detector in optical communicationwith the optical receiving path for determining a location of the objectwithin the field of regard and for determining a range of the object. Asecond transmitter is included for transmitting a pulsed optical beamwithin the field of regard in response to determining the location ofthe object. A processor is programmed to respond to outputs of thedetector to detect the location of the object in a first mode byprocessing signals in a first frequency band, and to determine the rangein a second mode by processing signals in a second, (e.g., wider and/orhigher) frequency band.

An apparatus is disclosed for detecting a location (e.g., azimuth andelevation) and range of an object within a field of regard. Such anapparatus includes means for transmitting energy as an optical beamacross the field of regard to determine a location of an object within afield of regard, and means for transmitting a pulsed optical beam withinthe field of regard in response to determining the presence of theobject. Means are disclosed for receiving energy reflected from anobject within the field of regard via a first optical receiving path.The apparatus includes means for determining the location of the objectin a first mode by processing signals from the receiving means and thedetecting means in a first frequency band, and means for determining arange to the object in a second mode by processing signals received viathe receiving means and the detecting means in a second, frequency band,the range of the object being determined using the pulsed optical beam.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

FIG. 1 illustrates a flow chart illustrating an exemplary operation ofan apparatus as described herein;

FIG. 2 illustrates an apparatus for detecting location and range to anobject according to an exemplary embodiment;

FIG. 3 illustrates an apparatus for detecting the location and range toan object according to another exemplary embodiment; and

FIG. 4 illustrates a time sequence of responses according to anotherexemplary embodiment.

DETAILED DESCRIPTION

FIG. 1 illustrates an exemplary method 100 of detecting a location(e.g., azimuth and elevation, or pitch) and range of an object within afield of regard wherein a multifunction detector includes multiple modefunctionality, such as an integrated focal plane array (FPA) functionand an integrated read-out integrated circuit (ROIC) function. A systemincluding such a detector can be operated in multiple modes to, forexample, identify/detect an object's presence and location (e.g.,azimuth and elevation) and also to determine a range to the object. Aprocessor associated with, or included in the detector, is programmed torespond to outputs of the focal plane array and read-out integratedcircuit in a first mode to process signals in a first (e.g., narrowerand/or lower) frequency band, and in a second mode to process signals ina second (e.g., wider and/or higher) frequency band relative to thefirst band. The processor can perform processing, such as double samplecorrelation (DSC) to analyze a return from the object during thedetection process.

According to the method 100, a system transmits energy, such as anoptical beam of a laser along a first direction within the field ofregard in block 102 to illuminate a target object. The laser can be anytype of suitable laser device including, but not limited to, a gatedcontinuous wave laser beam. The laser can be a single laser which isused to illuminate the field of regard for purposes of determining theobject's location, and which is then operated in a pulse mode todetermine a range to the object. Alternately, the laser can include afirst laser (e.g., CW laser) which is dedicated to the locationdetection, and a second laser (e.g., pulse laser) dedicated to rangedetection. Regardless of whether one or multiple lasers are used,exemplary embodiments include a single (e.g., common) optical receivingpath for receiving optical energy that can be used by the multifunctiondetector to determine both object location and object range.

The optical beam used for both object location and range detection canbe transmitted at any suitable frequency (wavelength) for detectingretro-reflections including, but not limited to infrared frequencies.Alternately, a first frequency (wavelength) can be used for objectlocation detection and a second frequency (wavelength) can be used forrange detection, provided the multifunction detector is configured toreceive reflections of the frequencies used for both object location andrange detection. Where the optical beam used for location detection is agated continuous wave optical beam transmitted during specifiedintervals, little or no energy is transmitted between intervals. If theoptical beam reaches an object having a retro-reflecting surface, forexample, an optical or electro-optical target, retro-reflected energy isreceived via the optical path of the multifunction detector in block104. Those skilled in the art will appreciate that such a beam can beselected of sufficient amplitude (e.g., by way of empirical data) to bedistinguishable from anticipated noise, such as reflections off theatmosphere.

Reflections received via the optical receiving path in block 104 areinput to a focal plane array and a read-out integrated circuit of themultifunction detector. The multifunction detector can be any suitabledevice which is responsive to the retro-reflected optical beam. Forexample, the detector can include an integrated quantum well based focalplane array and a read-out integrated circuit with processing thatimplements double sample correlation (e.g., compares a laser “on”condition to a laser “off” condition) to identify differences as anindication of a retro-reflector in the field of regard. Using a focalplane array, an orientation of the energy reflected from theretro-reflecting surface can be determined based on the location atwhich the energy impacts the array. The multifunction detector caninclude components (e.g., FPA photodiodes and ROIC preamplifiers) whichspan a bandwidth sufficient to accommodate the location detection laserfrequency and a relatively higher frequency, wider bandwidth narrowpulse return of the range detection laser frequency. Thus, regardless ofwhether two separate lasers are used, the FPA and ROIC can be configuredto be responsive to frequencies (wavelength) used for location and rangedetection.

Using common optics of the same optical receiving path, a signalreceived with the laser being turned on can be compared against a signalreceived when the laser is off. Spatial differences between thereflected and passive scene waveforms being sampled can then be used toidentify an existence of a retro-reflector in the field of regard. Forexample, the system can compare an unilluminated scene with a laserilluminated scene to highlight the presence of the detector in the fieldof regard. The focal plane array can, for example, be an InGaAs FPAoperating at room temperature, or an InSb detector (e.g., for detectinginfrared (IR) wavelengths in, for example, the 3-5 μm band, or lesser orgreater).

Thus, multiple (e.g., successive) signals representing reflected energyreceived at the detector can be compared to perform a target objectdetection via the continue scan block 108. If the difference betweenthese signals (e.g., between two or more successive signals) is greaterthan an established detection threshold, then it can be concluded that aretro-reflecting object is present at a coordinate location in the fieldof regard which is determined as a function of the direction from whichthe reflected energy was received, as represented in block 106.

When a detection (e.g., amplitude) threshold is exceeded on a locationof the FPA, a range detection can be performed. A ranging pulse can thenbe transmitted in block 112 toward the location in the field of regardat which the target was detected. Where the same laser which transmittedthe beam in block 102 is used to transmit a ranging pulse in block 112,no steering of the laser is necessary. However, where a separate, secondlaser is used to transmit a ranging pulse, the direction in which thepulse is transmitted may, for example, be steered as a function of thedetected object location. Such steering can be performed using anyavailable steering means (e.g., any mechanical and/or electrical drivefor pointing the second laser).

In an exemplary embodiment, the ranging pulse is transmitted within aranging interval, during which the first laser is not transmitting intothe field of regard. Thus a ranging pulse can be transmitted during aranging interval, at a time between the specified optical beamtransmission intervals, during which little or no energy is otherwisetransmitted.

The ranging pulse can be generated in any suitable manner. The rangefinding operation can, for example, be performed during an intervalfollowing a trailing (e.g., falling) edge of a continuous wave (CW)laser waveform. An optical pulse can be generated by a pulse laser foruse in range finding.

In an exemplary embodiment, the ranging pulse can have a duration whichis substantially less (e.g., an order of magnitude, or lesser orgreater) than the off cycle of the CW laser, and can be such thatspectral content of the pulse (e.g., MHz) is detectably different thanthe emission of the CW laser. The ranging pulse can be transmittedduring the ranging interval; for example, during the interval betweensuccessive transmissions of the optical beam, The pulse can betransmitted as a narrow pulse of high frequency content. Those skilledin the art will appreciate that a narrower pulse can be used to provideincreased range resolution.

In an exemplary embodiment, when a detection threshold is exceededwithin a given location of the FPA, the ranging pulse is transmittedduring the next available ranging interval, so that little or noadditional steering of one or more of the detector array, laser, or theoptics is performed. Rather than awaiting ranging laser pointing, aranging pulse can be immediately transmitted.

The multifunction detector receives the return of the ranging pulse viathe optical receiving path in block 114. Because the same optical paththat was used to receive energy for detecting the object location isused for range detection, the position of the multifunction detector inwhich the object's location was identified can be examined during theranging operation to detect the return of the ranging pulse. Forexample, a multiplexer included with the multifunction detector can beaddressed to select an output from a given location (or locations) ofthe FPA at which the object's location was detected. By addressing thisoutput location, the energy received can be examined subsequent totransmission of the optical pulse to look for the pulse return. Therange to the retro-reflecting object can be determined in block 116based on the time delay in receiving the return of the optical pulse. Adisplay function in block 118 can then be used to show the location,range of the object, time at detection, and any desired settings orcharacteristics of the detection system.

The multifunction detector can be sensitive to wavelengths of thetransmitted continuous wave optical beam and the optical pulse.

The ranging detection can be performed by an addressable one of aplurality of detector elements in the focal plane array. The focal planearray can be integrated with the read-out integrated circuit, and apreamplifier can be included in the ROIC for each of the FPA detectorelements. A multiplexer capable of selecting a specified output for anyof the individual FPA detector elements can include a channel for eachof the preamplifiers. The focal plane array can be any suitable opticalsensing device, and in an exemplary embodiment, is a 1×512 pixel linearfocal plane array of photodiodes or other photosensitive devices. Thefocal plane array can also be a linear focal plane array having a smallnumber of adjacent detector elements (e.g., pixels) whose output can beaveraged or otherwise combined. The linear focal plane array can bescanned to create a two dimensional field of regard. The focal planearray can be alternately configured as a two-dimensional array of anydesired dimension.

In an exemplary embodiment, a vertical optical beam used for objectlocation detection is scanned across the field of regard in onedirection (for example, horizontally), and the focal plane array has itslong dimension in another direction (for example, vertically). In thismanner, a vertical array of pixels define an instantaneous field of viewin a vertical direction for a vertical line of detector elements where alaser having optics for creating a vertical line is used as anilluminator. The horizontal scan of the vertical line defines the fieldof regard. The focal plane array can also be arranged with its longdimension in other than a vertical direction, with the scanningdirection being oriented at 90 degrees to the long dimension of thefocal plane array.

The scanning of the optical beam, and/or the focal plane array can beaccomplished by any known means for scanning. For example, scanning canbe accomplished using a means, such as a drive motor, for rotating atleast a portion of the system that contains the laser used for objectillumination, and/or the detector (e.g., the linear focal plane array).For example, a mirror which rotates through any angle up to 360 degreescan be included. In an exemplary embodiment, the mirror rotates throughan angle of about 180 degrees. Alternately, for example, the entirelaser apparatus can be rotated through the desired scan angle.

FIG. 2 illustrates schematically an apparatus, or system, 200 having amultifunction detector and common receiving path as described herein fordetermining a location of an object within a field of regard during afirst mode of operation, and for determining a range to the objectduring a second mode of operation. The apparatus is adapted to detectobjects, such as those which have retro-reflective surfaces.

The multifunction detector 220 can include an optical receiving path209, containing any desired optics and/or waveguide, in conjunction withan FPA and ROIC to determine the presence and location of the objectwithin the field of regard during a first mode of operation, and also todetermine a range to the object during a second, mode of operation. Thesame detector element (such as a pixel in a focal plane array) of whichthe object's location was detected in the first mode can be used todetermine range in the second mode. Alternately, a second detectorelement (such as a second pixel) having a fixed relationship to a firstdetector element (at which an object's location was detected), can beused to determine object range. For example, the second pixel can be apredetermined number of pixels away from the first pixel.

In an exemplary embodiment, the detector 220 includes focal plane array212 and associated (e.g., integrated) read-only integrated circuit 214.The focal plane array can include one or more elements, such as a photosensitive transistor pair, or other device responsive to frequencies(wavelengths) used for both the optical beam and the optical pulse. Thefocal plane array which includes the plurality of detector elements canbe coupled with the integrated read-out integrated circuit 214. In anexemplary embodiment, the multifunction detector includes 512 detectorelements in a 1×512 linear focal plane array, 512 preamplifiers withinROIC 214, and two 512 channel multiplexers 216.

The ROIC can include a number of preamplifiers corresponding to each ofthe detector elements in the focal plane array 212. The read-outintegrated circuit 214 can include an imaging channel and a pulsechannel multiplexer that can be used for addressing each of thepreamplifiers and thereby gate a specific output (or outputs) of the FPAto a rangefinder. The rangefinder determines the time interval betweentransmission of a ranging pulse and receipt of a return, and outputs arange determination. Each of the plurality of channels in themultiplexer 216 is thus associated with one of the preamplifiers. Therange to the object can be determined by the time between thetransmitted optical pulse being generated by the pulse laser 204 and thereturn from the optical pulse being detected.

In the FIG. 2 embodiment, a first transmitter 202 is provided fortransmitting energy as an optical beam across the field of regard. Theapparatus 200 includes the at least one focal plane array 212 having oneor more energy (e.g., light energy) sensitive elements 210, and anassociated read-out integrated circuit 214. As already mentioned, thefirst transmitter can be operated in a second mode to transmit anoptical energy pulse. For example, a laser with a mode lock capability(e.g., mode locked with a pockel cell or electro-optical modulator, orother suitable device) can be used to transmit an optical beam in onemode, and can be mode locked to transmit an optical pulse in a secondmode. Alternately, an optional second transmitter 204 can be providedfor transmitting an optical energy pulse within the field of regard inresponse to determining the location (e.g., azimuth and elevation) ofthe object.

A means, such as an optical receiving path, is provided for receivingenergy reflected from an object within the field of regard via a firstoptical receiving path. In an exemplary embodiment, the processor 240 isprogrammed to operate the focal plane array and read-out integratedcircuit in a first mode to process signals in a first frequency band,and in a second mode to process signals in a second (e.g., wider andhigher) frequency band.

The first transmitter 202 can be any type of suitable transmitter forgenerating an optical beam. For example, the first transmitter 202 canbe a gated CW laser, producing a gated continuous optical beam. Theoptical beam generated by the first transmitter 202 can have atransmitting interval and a ranging interval, wherein little or nooptical energy is transmitted by the first transmitter 202 during theranging interval.

In operation, the photosensitive elements in the focal plane array areeach available to receive retro-reflected energy. The photosensitiveelements and preamps can be wide band to also respond to the laserpulse, and can be low noise for optimal target object detection. Whenoptical energy is received, the photosensitive elements of the focalplane array 212 in conjunction with the preamplifiers 214 of the ROICeach generate an electrical voltage corresponding to the amount ofenergy received at each detector. The amplified voltage is transmittedto a target detection subsystem 230.

The target detection subsystem 230 can use a double sample correlation(DSC) detection process to determine whether a retro-reflection havingan energy sufficient to indicate a target is present. An integrationprocess collects photons over the sensitive optical waveband firstduring the illuminated state and secondly during the passive state. Thetarget detector subsystem 230, which can be configured as part of theROIC can include a double sample correlator (DSC) for each channel ofthe multifunction detector. A channel can be associated with eachphotosensitive element, or with each selected group of photosensitiveelements when outputs are, for example, averaged. The DSC compares thereflected signal received in response to illumination of a target areadue to transmission of the optical beam, with the energy levelcorresponding to a time interval when little or no optical energy istransmitted or received. If the difference in energy level detectedwithin any given channel is greater than a given detection threshold, aprocessor 240 stores the physical address of a multiplexer associatedwith the channel that received the optical energy.

The physical address of the multiplexer associated with a detectorelement 210 that received energy above a threshold level corresponds toa location (azimuth and elevation) of the object within the field ofregard, such as a two-dimensional coordinate for the object on the FPA.The same optical receiving path and detector element 210 which receivedthe reflections from the optical beam is then used to detect receipt ofthe returned optical pulse during a ranging mode.

During a ranging mode, the first (or optionally, a second) transmitter204 transmits the wider band optical pulse in the direction of theobject detected. The reflected optical pulse is received via the opticalreceiving path by a detector element 210 of the focal plane array 212,and the detector 210 generates an electrical voltage responsive to thereceived optical pulse, which is amplified by a correspondingpreamplifier within the ROIC 214. The output of a specified preamplifier214 is selected via a multiplexer 216 which is addressed by the targetdetection subsystem, and the multiplexed signal is transmitted to arange finding subsystem 270.

A range finding subsystem 270, under control of the processor 240,determines the range to the target by computing the difference betweenthe transmitted time of the optical pulse and the received time of thereturned pulse. A display 260 can be provided to illustrate thetwo-dimensional location as well as the range of the object.

The range finding subsystem 270 includes a high pass filter 278 and agated comparator 279. The pulse detection subsystem 270 receives on theFIG. 2 channel “A” a signal which can correspond to either theretro-reflected optical beam 294 or the returned optical pulse 276 viaoptical receiving path 209. The optical pulse return signal 218 is gatedby the multiplexer only during the interval when the illumination laseris off. The high pass filter 278 reduces an effect of the target objectidentification response to the retro-reflected optical beam during theobject location mode, and the effect of scan movement induced scenecontent. The gated comparator 279 receives the signal corresponding tothe reflected optical pulse 276 for processing the range to the object

FIG. 3 illustrates an embodiment of an apparatus having an FPA/ROICintegrated target object detection processor. In FIG. 3, the ROIC 320can include the focal plane array 212, preamplifiers 214, and high speedmultiplexers 216, as well as the components of the target detectionsubsystem 230, including a DSC scene processor comprised of sign changermultipliers 322, integrators 324, and pixel multiplexers 326 for eachchannel. In an exemplary embodiment, each of the multipliers 322, theintegrators 324, and the multiplexers 326 have a number of channelscorresponding to the number of detector elements 210, the number ofpreamplifiers 214, and the number of channels in the high speedmultiplexer 216.

The output of each preamplifier 214 is transmitted through channel B tothe multiplier 322. The output of each channel of the multipliers 322 isinput to the integrator 324. The control signal DUMP 332 begins theintegration of the integrator 324 and also enables the gated comparators330. The integrators 324 produce analog outputs which can be routed viaone or more multiplexers to one or more comparators. Those skilled inthe art will appreciate that digital circuits can of course be used inplace of any analog circuitry.

Together, the multipliers 322 and the integrators 324 form the doublesample correlator which compares the output of the preamplifier during atransmitting interval of the continuous wave laser to the output of thepreamplifier during the period when the continuous wave laser is nottransmitting. The gated comparators 330 compare the output of themultiplexed integrated signal with a detection threshold for eachdetector. If the signal exceeds the threshold, the processor indicatesthat a target has been detected at a given location within the FPA thatis then used for a ranging detection.

Additional exemplary features and functions of the apparatus 300 areillustrated by way of FIG. 4, which illustrates a representative timesequence of responses of the apparatus according to an exemplaryembodiment. The first trace 410 represents a control signal which gatesthe continuous wave illumination laser 204 that transmits an opticalbeam during a first mode of operation. The optical beam is transmittedby transmitter 204 for a time period T1, and is prevented fromtransmitting by any suitable means, for a time period T2. The timeperiod T2 is a ranging interval during a second mode of operation inwhich the ranging pulse is transmitted by a pulsed laser. The low-passfilter formed by the integrator limits the response to any optical pulsereturns which may occur during this interval.

The second trace 420 in FIG. 4 illustrates the output signal of the highspeed multiplexer 216 of FIGS. 2 and 3 for one channel.

Third trace 460 is the digital DUMP signal used to begin a newintegration cycle and to enable comparison function.

During the first cycle 430 of T2 and T1 intervals in the first trace410, the output of the multiplexer 216 is zero as shown in the secondtrace 420. The second trace 420 illustrates a frequency spectral contentsignal 422 which corresponds to energy received at a detector during thesecond interval 440.

The interval 450 of the first trace illustrates transmission of aranging pulse 270 by the ranging pulse laser 202 after detection ofenergy above a threshold in a specific location of the FPA during thesecond interval 440.

An integrated narrow band signal corresponding to the retro-reflectedcontinuous wave illumination beam 272 is illustrated in the fourth trace470 of FIG. 4. The input to the FIG. 2 multiplexer 216 contains bothnarrow band and wide band signal components. During the interval 430 ofthe first trace, no active reflectance is detected (the signal is lowerthan the detection threshold 426).

As a result, the output of the gated comparator 330 is zero, as seen inthe fifth trace 480 of FIG. 4. During the second interval 440 in FIG. 4,a detector detects a large active reflectance (the trace 470 is abovethe detection threshold 426). For example, during the period when thecontinuous wave laser is transmitting (T1 of interval 440), the non-zerosignal 422 (see FIG. 4) is transmitted to the multiplier 322 andintegrator 324.

The resulting integrated signal 428 exceeds the detection threshold 426.The slope of the trace of the signal 428 in FIG. 4 can be an indicationof the strength of the retro-reflected signal.

At the time when the detection threshold is exceeded, the processorcontrols the range pulse laser 204 so as to transmit the range pulse 272in a direction toward the target detected by the target detectionsubsystem. In an exemplary embodiment, the range pulse laser 204transmits the ranging pulse before any additional gated optical beamsare transmitted, e.g., during the subsequent ranging interval T2 ininterval 450.

As illustrated in the fifth and sixth traces 480 and 490 in FIG. 4, therange pulse is transmitted and received during the period in which thecontinuous wave laser is “OFF” (the ranging interval T2 in interval450). When the pulse detection subsystem detects the returned pulse, therange to target can be determined by the time between the transmittedpulse and the received pulse. The sixth trace 424 in FIG. 4 illustratesthe output of a high pass filter, such as high pass filter 278, in whichonly the narrow band signal 424 is output to the pulse detectionthreshold comparator. The high pass filter 278 rejects unwanted lowfrequency scene components while propagating the higher frequencyspectral content of the retro-reflected optical pulses.

It will be appreciated by those skilled in the art that the presentinvention can be embodied in other specific forms without departing fromthe spirit or essential characteristics thereof. The presently disclosedembodiments are therefore considered in all respects to be illustrativeand not restricted. The scope of the invention is indicated by theappended claims rather than the foregoing description and all changesthat come within the meaning and range and equivalence thereof areintended to be embraced therein.

What is claimed is:
 1. A multifunction detector for detecting energyreflected from a surface of an object, the detector comprising: anoptical receiving path; a focal plane array in communication with theoptical receiving path; and a read-out integrated circuit incommunication with the optical receiving path, integrated with the focalplane array; and a processor programmed to operate the focal plane arrayand read-out integrated circuit in a first mode to process reflectedsignals from a continuous wave laser beam operating in a first frequencyband to determine an existence of the object, and in a second mode toprocess reflected signals from a laser pulse in a second frequency bandto determine a range of the object.
 2. Detector according to claim 1,wherein the detector implements double sample correlation to identifydifferences between signals collected during a first time period in theabsence of the continuous wave laser beam and signals reflected from thecontinuous wave laser beam collected during a second time period as anindication of a retro-reflector presence in a field of regard of thedetector.
 3. Detector according to claim 1, wherein the focal planearray is a linear focal plane array.
 4. Detector according to claim 3,comprising: means for scanning the linear focal plane array.
 5. Detectoraccording to claim 1, wherein the read-out integrated circuit includes anumber of pre-amplifiers which correspond to each of a plurality ofpixels in the focal plane array.
 6. Detector according to claim 5,wherein the read-out integrated circuit includes an imaging channel anda pulse channel multiplexer for each preamplifier.
 7. Detector accordingto claim 1, wherein the focal plane array is a two-dimensional array. 8.The multifunction detector of claim 1, wherein the focal plane arraycomprises a plurality of detector elements; and wherein the processor isfurther programmed to: identify a particular detector element thatdetected the reflected signals from the continuous wave laser beam fromwhich the existence of the object was determined; and process only thosereflected signals from the laser pulse received by the particulardetector element to determine the range of the object.